1. Volume 14, Issue 3, Pages 469-476 (March 2006)
The Structural Basis of Actin Interaction with Multiple WH2/β-Thymosin Motif-Containing Proteins 
Adeleke H. Aguda, Bo Xue, Edward Irobi, Thomas Préat, Robert C. Robinson 
Structure 
Volume 14, Issue 3, Pages (March 2006)
DOI: /j.str
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2. Figure 1 Hybrid Protein Design
(A) Structural-based sequence alignment of WH2/Tβ domains. Yellow, Tβ4-like residues within the C-terminal half; pink, functionally analogous residues in both gelsolin and WH2/Tβ domain families; gray, Tβ4-like residues within the N-terminal half; blue, conserved residues throughout the WH2 family, with the exception of Tβ4. Accession numbers are: gelsolin (X04412), Tβ4 (NM_021109), ciboulot (Cib, NM_167001), TTβ (NM_077029), actobindin (Act, A36614), N-WASP (NM_003941), WASP (U12707), WAVE1 (BC044591), WAVE2 (AB026542), and WAVE3 (AB026543).
(B) Design of hybrid proteins. The coloring scheme of WH2/Tβ domains is the same as that used in (A).
Structure  , DOI: ( /j.str )
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3. Figure 2 Structures of G1-Cib23:Actin and G1-Nw2:Actin Complexes
(A) Front view of G1-Cib23:actin. Actin is shown in light blue (subdomains labeled 1–4); ATP is drawn in orange (ball-and-stick), and the associated calcium ion is shown as a green sphere. The G1 portion of the hybrid (residues 27–149) is shown in tomato, and the G1 bound calcium ions are represented by purple spheres. The golden portion of the hybrid represents the G1 sequence that is analogous to ciboulot (residues 69–72) and N-WASP (residues 419–422). The Cib2 portion is shown in green (residues 73–89).
(B) A 90° rotation of (A) around the vertical axis.
(C) Front view of G1-Nw2:actin. Actin and gelsolin retain the colors as in (A). The Nw2 portion is in green (residues 423–425).
(D) A 90° rotation of (C) around the vertical axis.
Structure  , DOI: ( /j.str )
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4. Figure 3
Comparison of Actin Bound WH2/Tβ Domain Superimposed Structures
(A) The WH2/Tβ chains are shown as Cα traces, and the actin protomer is shown as a ribbon representation (light blue). Cib2 is drawn in light green, Tβ4 (Irobi et al., 2004) is drawn in pink, Cib1 (Hertzog et al., 2004) is drawn in purple, and N-WASP is drawn in black.
(B) A 90° rotation of (A) around the vertical axis.
(C) Comparison of the actin structures from G1-Cib23:actin (blue) and G1-Nw2 (yellow) through superposition of subdomain 4.
Structure  , DOI: ( /j.str )
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5. Figure 4
Binding of Whole Ciboulot and Its Single Domains to Actin as Revealed by EDC Crosslinking
(A and B) In these experiments, the actin concentration was 4 μM, and the concentrations for Cib123, profilin, gelsolin, and synthetic peptides were 4 μM, 4 μM, 1.4 μM, and 20 μM, respectively. Reactions were conducted at 20°C for 1 hr. (A) Cib2 and Cib3 peptides (MW 5 kDa) can be crosslinked to both G- and F-actin, while a randomly selected peptide (Ctrl) cannot be crosslinked under the same conditions (1.4 mM EDC and sulfo-NHS). S and P denote fractions from supernatant and pellet, respectively. The gel was stained with Coomassie blue. Crosslinked cibolout/actin species move with a slightly higher apparent molecular mass than actin alone (denoted by an asterisk). (B) A Western blot probed with an anti-actin antibody demonstrating that Cib123 interacts with more than one actin under nonpolymerizing conditions. Cib123 (15 kDa), profilin (15 kDa), and gelsolin (88 kDa) were crosslinked to actin (43 kDa) at two concentrations of crosslinker (1.4 and 4 mM). Untreated and crosslinked actin alone are included for comparison, and the migration of monomeric actin is marked by an asterisk. The band migrating slightly slower than the 101 kDa marker (Actin + Cib123 at 1.4 mM EDC lane) displays an apparent molecular mass appropriate for the 1:2 Cib123:actin complex (101 kDa).
Structure  , DOI: ( /j.str )
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6. Figure 5 Model of Interaction of Cib123 with G-Actin
(A) A model of Cib123 bound to three actin monomers (coral). The N-terminal half of each ciboulot domain is shown in purple, and the C-terminal half is shown in yellow. The pointed end cap is labeled “1,” the barbed end cap is labeled “3,” and the inter-Tβ connections are labeled “2.”
(B) An actin filament model constructed from ADP-rhodamine-actin monomers arranged in the Holmes orientation (Burtnick et al., 2004; Holmes et al., 1990; Otterbein et al., 2001). Actin protomers are shown in light blue and cyan. The green arrows signify the conformational changes in ciboulot that are required to allow the actin monomers in (A) to condense into the filament (black arrows).
Structure  , DOI: ( /j.str )
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7. Figure 6
Schematic Models of the Mechanism of F-Actin Interaction with Tβ Proteins When Bound to More Than One Actin Monomer
(A) Possible interactions with TTβ (black) and actobindin (Act, purple). G-actin and F-actin protomers are depicted in green and light blue, respectively.
(B) Possible interactions of ciboulot (Cib, yellow) with actin. In this mechanism, at the barbed end of the filament (+), the N-terminal helices are proposed to be released by the actin G- to –F-actin transition, while, at the pointed end (−), the C-terminal cap is unaffected by the state of actin. Red crosses signify capped filaments (Irobi et al., 2004).
Structure  , DOI: ( /j.str )
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